Controlling the outcome of reactions in macromolecular systems: Measurement of structural dynamics during synthesis and degradation in biologically relevant polymers

控制大分子系统中的反应结果：生物相关聚合物合成和降解过程中结构动力学的测量

• 批准号: RGPIN-2018-05444
• 负责人: Tokarz, Danielle
• 金额: $ 1.75万
• 依托单位: Saint Mary's University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=713685
• 关键词: Controlling; outcome; reactions; macromolecular; systems

One of the greatest challenges to understanding how molecules and polymers in living biological tissues interact is the inability to characterize both chemical structure and function in undisturbed biological tissues. Chemical additives enable contrast in biological tissues however, with limitations such as requiring genetic manipulation or dyes suffering from photobleaching, quick digestibility, or cytotoxicity and unintended alterations. Importantly, effects of structural heterogeneity between neighbouring proteins or polymers are difficult to assess since structural analysis techniques typically require purified samples or lack biocompatibility. In the proposed research, we will take advantage of the nonlinear optical properties of molecules and polymers to discover how biologically relevant polymers assemble, degrade and repair in undisturbed tissues. To achieve this goal, we will use a combination of different advanced nonlinear optical analysis techniques and develop novel instrumentation for characterizing the structural properties of polymers. The proposed instrumentation will be the first system in Canada and one of a handful in the world to perform fast nonlinear optical characterization of polymer structural properties. This research will allow advanced and world class training opportunities for students. Understanding how biologically relevant polymers assemble, degrade and repair will provide new developments in agricultural and pharmaceutical research. For instance, insight into the structural changes of collagen in the extracellular matrix during ageing will be studied which has applicability in developing organ scaffolds, and new pharmaceuticals. Further, novel insights into the complex structure and digestion properties of cellulose, chitin and starch has tremendous impact on global food, biofuels, pulp and paper, textile and biodegradable materials industries, with potential for spin-off companies enabling the next generation of Canadian entrepreneurs. Finally, an improved understanding of photosynthesis has applications in increasing plant growth efficiency, growing plants in colder climates and increasing global food supply. This knowledge may also be implemented to develop advanced artificial solar cells, enabling solar cells with dynamic antenna for improved efficiency collection during low light conditions.

了解活的生物组织中的分子和聚合物如何相互作用的最大挑战之一是无法表征未受干扰的生物组织的化学结构和功能。然而，化学添加剂能够在生物组织中形成对比，具有局限性，如需要基因操作或染料遭受光漂白、快速消化、细胞毒性和意外改变。重要的是，相邻蛋白质或聚合物之间的结构异质性的影响很难评估，因为结构分析技术通常需要纯化的样品或缺乏生物兼容性。 在这项拟议的研究中，我们将利用分子和聚合物的非线性光学性质来发现生物相关聚合物如何在未受干扰的组织中组装、降解和修复。为了实现这一目标，我们将结合使用不同的先进非线性光学分析技术，并开发新的仪器来表征聚合物的结构性质。拟议中的仪器将是加拿大的第一个系统，也是世界上为数不多的对聚合物结构性质进行快速非线性光学表征的系统之一。这项研究将为学生提供先进的世界级培训机会。 了解与生物相关的聚合物如何组装、降解和修复将为农业和制药研究提供新的发展。例如，将深入了解老化过程中细胞外基质中胶原的结构变化，这将适用于开发器官支架和新药物。此外，对纤维素、甲壳素和淀粉的复杂结构和消化特性的新见解对全球食品、生物燃料、纸浆和造纸、纺织和可生物降解材料行业产生了巨大影响，并有可能为剥离公司提供支持，帮助下一代加拿大企业家。最后，更好地理解光合作用在提高植物生长效率、在较冷的气候中种植植物以及增加全球粮食供应方面都有应用。这一知识也可用于开发先进的人造太阳能电池，使太阳能电池具有动态天线，以提高在弱光条件下的收集效率。